CN113870676A - Fault simulation device and method - Google Patents

Abstract

The invention provides a fault simulation device and a fault simulation method, which relate to the technical field of tectonic geology physical simulation and comprise a first platform, a second platform, an inclined sliding bedplate and a driving mechanism, wherein the inclined sliding bedplate comprises a first bedplate and a second bedplate, the first bedplate is connected with the first platform, and the second bedplate is connected with the second platform; the first bedplate is attached to the second bedplate, and an attaching surface between the first bedplate and the second bedplate is inclined relative to a first table top of the first platform; the driving mechanism is used for driving the first platform and the second platform to perform relative linear displacement, relative torsional displacement or relative linear superposition torsional displacement along the binding face. The invention simulates the tension-torsion deformation, the pressure-torsion deformation, the pivot fault deformation and the like under the condition of the existing fault and the mutual superposed deformation among the tension-torsion, the pressure-torsion and the pivot fault by arranging the first platform, the second platform, the inclined sliding platform plate and the driving mechanism.

Description

Fault simulation device and method

Technical Field

The invention relates to the technical field of tectonic geology physical simulation, in particular to a fault simulation device and a fault simulation method.

Background

In the basin construction process, the phenomenon of multi-stage fault superposition deformation is frequently developed, so that the recognition and the understanding of the multi-stage fault superposition deformation process are important for researching the basin formation mechanism in the field of tectonics. The relative motion of the two disks of the fault can be divided into direct movement and rotation motion. In the translational motion, the two disks relatively slide straightly without rotation, and the two broken disks are still parallel after parallel linear motion before dislocation, such as pressing and twisting or stretching and twisting. In the rotating motion, the two disks relatively rotate and slide by taking the normal line of the section as an axis, and the two disks are not parallel to each other after parallel linear motion before dislocation, such as a pivot fault. The hinge fault is an important structural deformation in the basin structure, and from the mechanical property, one end of the hinge fault is pressed, and the other end of the hinge fault is pressed, so that the hinge fault is a very typical rotating motion fault.

Due to the limitation of experimental conditions, the simulation of fracture multi-phase superposition mostly focuses on researching the superposition deformation of translational motion faults such as pressure torsion or tension torsion, and the like, but cannot completely reduce the process of the superposition deformation of the multi-phase junction faults. There is therefore a need to further resolve the important geological processes of multi-phase fault stack deformation where there is a junction fault deformation under preexisting fractures. At present, in the structural physical simulation experiment, researchers have long paid much attention to basic research on pressure torsion, tension torsion, junction fault and the like. However, the existing experimental device still has certain defects, and can not more scientifically and intuitively simulate the hinge deformation under different pre-existing angles and the control action and the structure evolution characteristics of the fault superposition deformation with the participation of the hinge fault in multiple stages.

Disclosure of Invention

The invention provides a fault simulation device and a fault simulation method, which are used for solving the defects that the existing experimental device in the prior art still has certain defects, can not simulate pivot deformation under different pre-existing angles more scientifically and intuitively, and control action and structural evolution characteristics of fault superposition deformation with pivot fault participation in a plurality of periods, and realize the fault simulation device and the fault simulation method.

The invention provides a fault simulation device which comprises a first platform, a second platform, an inclined sliding platen and a driving mechanism, wherein the inclined sliding platen comprises a first platen and a second platen, the first platen is connected with the first platform, and the second platen is connected with the second platform;

the first bedplate is attached to the second bedplate, and an attaching surface between the first bedplate and the second bedplate is inclined relative to a first table top of the first platform;

the driving mechanism is used for driving the first platform and the second platform to perform relative linear displacement, relative torsional displacement or relative linear superposition torsional displacement along the binding face.

According to the fault simulation device provided by the invention, the simulation device further comprises a controller, wherein the controller is electrically connected with the driving mechanism and is used for controlling the driving mechanism to drive the displacement speed, the displacement distance and the displacement direction of the first platform and the second platform to relatively linearly displace along the binding surface, or controlling the driving mechanism to drive the displacement speed, the displacement distance, the displacement angle and the displacement direction of the first platform and the second platform to relatively torsionally displace along the binding surface or relatively linearly superpose the torsional displacement.

According to the fault simulation device provided by the invention, the driving mechanism comprises a lifting mechanism and a first transverse moving mechanism, the lifting mechanism is connected with the second platform and used for driving the second platform to move up and down, and the first transverse moving mechanism is connected with the second platform and used for driving the second platform to move along the horizontal direction.

According to the fault simulation device provided by the invention, the driving mechanism comprises a second transverse moving mechanism which is connected with the first platform and is used for driving the first platform to move along the horizontal direction.

According to the fault simulation device provided by the invention, the driving mechanism comprises a rotating mechanism and a turnover mechanism, and the second platform is provided with a second table top;

the rotating mechanism is connected with the second platform and used for driving the second platform to rotate, and the rotating axis of the second platform is vertical to the second table top;

the turnover mechanism is connected with the second platform and used for driving the second platform to turn over, a turnover axis of the second platform is intersected with the rotation axis and is mutually vertical, and the plane where the turnover axis is located is vertical to the binding surface.

According to the fault simulation device provided by the invention, the first bedplate is detachably connected with the first platform, and the second bedplate is detachably connected with the second platform.

According to the fault simulation device provided by the invention, a first enclosing plate is arranged on the first platform, a second enclosing plate is arranged on the second platform, and the first enclosing plate and the second enclosing plate enclose to form a groove;

the first enclosing plate is connected with the second enclosing plate through a flexible plate.

Another object of the present invention is to provide a simulation method based on any of the above fault simulation apparatuses, including the steps of:

s100, controlling a binding surface in the inclined sliding table plate to incline at a certain angle relative to the first platform;

s200, laying at least one layer of quartz sand on a first platform and a second platform, wherein each layer of quartz sand is laid with a mark layer;

and S300, controlling the first platform and the second platform to perform relative linear displacement, relative torsional displacement or relative linear superposition torsional displacement along the binding surface.

According to the simulation method provided by the present invention, in the step S300, the superimposing of the relative linear displacement and the relative torsional displacement includes superimposing the relative linear displacement and the relative torsional displacement at intervals;

when the relative linear superposition torsional displacement is carried out, after one relative linear displacement or relative torsional displacement is carried out, at least one layer of quartz sand is paved on the uppermost layer, a mark layer is paved on each layer of quartz sand, and then the next relative linear displacement or relative torsional displacement is carried out.

According to the simulation method provided by the invention, in the step S300, in the relative linear displacement process, a plane image is obtained once every certain distance of displacement; during the relative torsion displacement, a plane image is acquired once every certain torsion angle.

According to the simulation method provided by the invention, after the step S300 is finished, at least one layer of quartz sand is paved on the uppermost layer, a certain amount of water is poured and placed still, and the section is longitudinally cut for obtaining the section.

The fault simulation device and the fault simulation method provided by the invention have the beneficial effects that: by arranging the first platform and the second platform, a binding surface is formed between the first platform and the second platform through the inclined sliding bedplate, and the binding surface is inclined with the first platform so as to be beneficial to simulating a pre-existing fault; and the driving mechanism drives the first platform and the second platform to perform relative linear displacement, relative torsion displacement or relative linear superposition torsion displacement along the binding surface so as to simulate the walking deformation of a tension torsion, a pressure torsion or a pivot under the condition of the existence of a pre-existing fault and the walking deformation of mutual superposition of the tension torsion, the pressure torsion and the pivot, wherein the oblique sliding platform plates with different inclination angles can be replaced to better simulate the walking deformation of various pre-existing angles.

Drawings

In order to more clearly illustrate the technical solutions of the present invention or the prior art, the drawings needed for the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and those skilled in the art can also obtain other drawings according to the drawings without creative efforts.

FIG. 1 is a schematic structural diagram of a fault simulation apparatus provided in the present invention;

FIG. 2 is a schematic structural diagram of a turnover mechanism and a rotation mechanism according to the present invention;

FIG. 3 is a second schematic structural view of the turning mechanism and the rotating mechanism provided by the present invention;

FIG. 4 is a schematic flow chart of a fault simulation method provided by the present invention;

FIG. 5 is a schematic diagram of a flip hinge of the simulation apparatus provided in the present invention;

FIG. 6 is a plan evolution diagram of a fault deformation simulation result of a right row piezoelectric torsion superposition pivot performed under a 75 ° pre-existing fault in an embodiment provided by the present invention;

FIG. 7 is a cross-sectional slice of a simulation result of fault deformation of a right row piezoelectric hinge superposition pivot performed under a 75 ° pre-existing fault in an embodiment provided by the present invention;

fig. 8 is a schematic structural diagram of an electronic device provided in the present invention.

Reference numerals:

1: a first platform; 11: a first table top; 12: a first enclosing plate;

13: a groove;

2: a second platform; 21: a second table top; 22: a second enclosing plate;

3: an inclined sliding bedplate; 31: a first platen; 32: a second platen;

33: a binding face;

4: a drive mechanism; 41: a lifting mechanism; 42: a first traversing mechanism;

43: a second traversing mechanism; 44: a rotation mechanism; 45: and (5) turning over the mechanism.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer, the technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings, and it is obvious that the described embodiments are some, but not all embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the embodiments of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "first" and "second", etc. are numbers that are used for clearly illustrating the product parts and do not represent any substantial difference.

In addition, all directions or positional relationships mentioned in the embodiments of the present invention are positional relationships based on the drawings, and are only for convenience of describing the present invention and simplifying the description, but do not imply or imply that the referred device or element must have a specific orientation, and are not to be construed as limiting the present invention. An XYZ coordinate system is provided in the present invention, wherein a forward direction of an X axis represents a right direction, a reverse direction of the X axis represents a left direction, a forward direction of a Z axis represents an upper direction, a reverse direction of the Z axis represents a lower direction, a forward direction of a Y axis represents a front direction, and a reverse direction of the Y axis represents a rear direction, wherein "up", "down", "front", "rear", "left", and "right" do not constitute a limitation on a specific structure, and are based on only positions in the drawings.

It should be noted that the description "in the range of …" in the present invention includes both end values. Such as "in the range of 10 to 20," includes both ends of the range of 10 and 20.

It is to be understood that, unless otherwise expressly specified or limited, the term "coupled" is used broadly, and may, for example, refer to directly coupled devices or indirectly coupled devices through intervening media. Specific meanings of the above terms in the embodiments of the invention will be understood to those of ordinary skill in the art in specific cases.

The fault simulation apparatus and simulation method of the present invention will be described below with reference to fig. 1 to 8.

Specifically, the present embodiment provides a fault simulation apparatus including: the device comprises a first platform 1, a second platform 2, an inclined sliding table plate 3 and a driving mechanism 4, wherein the inclined sliding table plate 3 comprises a first table plate 31 and a second table plate 32, the first table plate 31 is fixedly connected with the first platform 1, and the second table plate 32 is connected with the second platform 2;

specifically, the first platform 1 and the second platform 2 are used as sand-carrying platforms and can be in various shapes, in this embodiment, taking a square platform as an example, the first platform 1 and the second platform 2 are both square planes, and the length of the whole plane obtained after the first platform 1 is matched with the second platform 2 is within a range from 75 centimeters to 80 centimeters, preferably 78 centimeters; the width of the overall plane is in the range of 60 cm to 65 cm, preferably 64 cm.

The first platen 31 is attached to the second platen 32, and an attaching surface 33 between the first platen 31 and the second platen 32 is inclined with respect to the first table surface 11 of the first platform 1;

specifically, the inclined sliding platen 3 is composed of a first platen 31 and a second platen 32, both the first platen 31 and the second platen 32 are folding plates, upper half folding plates of the first platen 31 and the second platen 32 are respectively connected with the first platform 1 and the second platform 2, lower half folding plates of the first platen 31 and the second platen 32 are attached to form an attaching surface 33, and the attaching surface 33 refers to a general name of two attaching surfaces of the first platen 31 and the second platen 32.

The binding surface 33 is inclined relative to the first table top 11 of the first platform 1, that is, an included angle formed between the binding surface 33 and the first table top 11 is greater than 0, and the first platform 1 and the second platform 2 can slide along the direction of the binding surface 33, and the binding surface 33 forms a pre-existing fault layer to simulate tension and torsion, compression and torsion or hinge parallel under the condition that the pre-existing fault layer exists, or three of the three are mutually overlapped and deformed, or any two of the three are mutually overlapped and deformed.

The driving mechanism 4 is used for driving the first platform 1 and the second platform 2 to perform relative linear displacement, relative torsional displacement or relative linear superimposed torsional displacement along the joint surface 33.

Specifically, the relative linear displacement refers to that the first platform 1 and the second platform 2 perform relative linear displacement along the plane where the attachment surface 33 is located, and may be single linear displacement or multiple linear displacements, where the multiple linear displacements may be multiple linear displacements in the same direction or multiple linear displacements in different directions. The relative twisting displacement is that the first platform 1 and the second platform 2 are twisted relatively along a certain point in the plane of the joint surface 33, wherein the first platen 31 and the second platen 32 are always jointed during the relative twisting of the first platform 1 and the second platform 2. The relative linear superposition torsional displacement refers to that the first platform 1 and the second platform 2 perform relative linear displacement and relative torsional displacement on the plane where the binding surface 33 is located, wherein the linear displacement and the torsional displacement can be displaced step by step and can also be displaced simultaneously; and the torsional displacement can be superposed after multiple times of linear displacement, and other displacement modes of the torsional displacement superposed by the linear displacement can be realized.

In the embodiment, the first platform 1 and the second platform 2 are arranged, the binding surface 33 is formed between the first platform 1 and the second platform 2 through the inclined sliding table plate 3, and the binding surface 33 is inclined with the first platform 1 to facilitate simulation of a pre-existing fault; and the driving mechanism 4 drives the first platform 1 and the second platform 2 to perform relative linear displacement, relative torsion displacement or relative linear superposition torsion displacement along the binding surface 33 so as to simulate the walking deformation of a tension torsion, a pressure torsion or a pivot under the condition that a pre-existing fault exists and the walking deformation of mutual superposition of the tension torsion, the pressure torsion and the pivot, wherein the inclined sliding table plates 3 with different inclination angles can be replaced to better simulate the walking deformation of various pre-existing angles.

Specifically, the simulation device further comprises a controller, wherein the controller is electrically connected with a driving mechanism 4 and is used for controlling the driving mechanism 4 to drive the first platform 1 and the second platform 2 to follow the displacement speed, displacement distance and displacement direction of the binding face 33 in relative linear displacement, or is used for controlling the driving mechanism 4 to drive the first platform 1 and the second platform 2 to follow the displacement speed, displacement distance, displacement angle and displacement direction of the binding face 33 in relative torsional displacement or in relative linear superposition torsional displacement, so as to realize the automatic control of the simulation device.

Specifically, the driving mechanism 4 has various embodiments, wherein the driving mechanism 4 can respectively drive the first platform 1 and the second platform 2 to perform relative displacement, and can also fix the first platform 1 and only drive the second platform 2 to perform displacement. In this embodiment, based on the driving mechanism 4 of this embodiment, any specific device that can implement the functions of the driving mechanism 4 of this embodiment may be replaced or modified without creative work based on the driving mechanism 4 of this embodiment, and all of the devices fall within the protection scope defined by the present invention for the driving mechanism 4.

Specifically, the driving mechanism 4 according to the present embodiment includes a lifting mechanism 41 and a first traverse mechanism 42, the lifting mechanism 41 is connected to the second platform 2 and is configured to drive the second platform 2 to move up and down along the Z-axis direction, and the first traverse mechanism 42 is connected to the second platform 2 and is configured to drive the second platform 2 to move along the horizontal direction.

Referring to fig. 1, the lifting mechanism 41 is disposed below the second platform 2, and mainly includes a telescopic cylinder and a guide frame, the guide frame is provided with a slide rod and a slide hole, and when the cylinder drives the second platform 2 to move up and down, the slide rod slides in the slide hole, so that the second platform 2 does not tip over during the up and down movement. Optionally, at least 3 oil cylinders are arranged below the second platform 2, and the 3 oil cylinders move synchronously to ensure the stability of the second platform 2 in ascending and descending.

The first traverse mechanism 42 includes an X-direction traverse mechanism and a Y-direction traverse mechanism, wherein the Y-direction traverse mechanism includes a first traverse motor and a Y-direction traverse slide rail, the first traverse motor is connected with the second platform 2, and the first traverse motor drives the second platform 2 to slide on the Y-direction traverse slide rail. Preferably, the lifting mechanism 41 is installed between the Y-direction traversing mechanism and the second platform 2, and the lifting mechanism 41 is linked with the Y-direction traversing mechanism to drive the second platform 2 to slide relative to the first platform 1 along the oblique up-down direction of the bonding surface 33.

Specifically, the X-direction transverse moving mechanism comprises a second transverse moving motor and an X-direction transverse moving slide rail, the second transverse moving motor is connected with the second platform 2, and the second transverse moving motor drives the second platform 2 to slide on the X-direction transverse moving slide rail. Preferably, the lifting mechanism 41 is installed between the Y-direction traversing mechanism and the second platform 2, the Y-direction traversing mechanism is installed on the X-direction traversing mechanism, and the X-direction traversing mechanism is installed on the fixed frame. The X-direction transverse moving mechanism can drive the second platform 2 to move along the X direction along the plane where the bonding surface 33 is located, and the X-direction transverse moving mechanism and the Y-direction transverse moving mechanism are linked with the lifting mechanism 41 to drive the second platform 2 to slide relative to the first platform 1 along any direction along the plane where the bonding surface 33 is located.

In this embodiment, by providing the X-direction traversing mechanism, the Y-direction traversing mechanism, and the lifting mechanism 41, the first platform 1 and the second platform 2 can be driven to relatively slide along any direction along the plane direction of the attaching surface 33, so as to simulate the tension-torsion and pressure-torsion deformation of the crust during movement when the crust has a fault.

Preferably, the driving mechanism 4 according to this embodiment further includes a second traverse mechanism 43, and the second traverse mechanism 43 is connected to the first platform 1 and is used for driving the first platform 1 to move along the horizontal direction. The second traverse mechanism 43 is similar to the first traverse mechanism 42, and may be provided with an X-direction traverse mechanism and a Y-direction traverse mechanism, in fig. 1, the second traverse mechanism 43 is provided with only the X-direction traverse mechanism, the second traverse mechanism 43 includes a third traverse motor and an X-direction traverse slide rail, and the third traverse motor is connected to the first platform 1 to drive the first platform 1 to slide along the X-direction traverse slide rail in the X direction, so as to accelerate the speed of the relative displacement between the first platform 1 and the second platform 2.

Specifically, the driving mechanism 4 described in this embodiment further includes a rotating mechanism 44 and a turnover mechanism 45, and the second platform 2 has a second table 21; the rotating mechanism 44 is connected with the second platform 2 and is used for driving the second platform 2 to rotate, and the rotation axis N of the second platform 2 is vertical to the second table top 21; the turnover mechanism 45 is connected with the second platform 2 and used for driving the second platform 2 to turn over, a turnover axis M of the second platform 2 is intersected with the rotation axis N and is mutually vertical, and the plane where the turnover axis M is located with the rotation axis N is vertical to the binding surface 33.

As shown in fig. 1 and fig. 5, the rotating mechanism 44 drives the second platform 2 to rotate, and the rotating mechanism 44 drives the rotation axis N of the second platform 2 to be perpendicular to the second table surface 21 of the second platform 2, that is, the rotating mechanism 44 drives the second platform 2 to rotate along the plane of the second table surface 21; the turnover mechanism 45 is used for driving the second platform 2 to turn over, the turnover axis M of the second platform 2 intersects with the rotation axis N of the second platform 2 and is perpendicular to each other, and the plane where the turnover axis M and the rotation axis N are located is perpendicular to the attaching surface 33. As shown in fig. 1, the turnover mechanism 45 is adapted to drive the turnover axis M of the second platform 2 to be parallel to the Y-axis, the attachment surface 33 is disposed to be inclined with respect to the first platform 1, and the second platform 2 is rotated by the rotation mechanism 44, so as to ensure that the first platform 1 and the second platform 2 pivot relatively along the attachment surface 33, and the first platen 31 and the second platen 32 are not separated from each other during rotation, so as to better simulate hinge deformation under a pre-existing fault, and hinge pressing, torsion stretching and hinge stacking deformation.

Preferably, the first platen 31 is removably attached to the first platform 1 and the second platen 32 is removably attached to the second platform 2. The first bedplate 31 and the second bedplate 32 have multiple models, the joint surface 33 formed after the first bedplate 31 and the second bedplate 32 with different models are jointed is different in inclination angle relative to the first platform 1, and the first bedplate 31 and the second bedplate 32 with different angles are replaced to simulate the pre-existing faults with different angles.

Specifically, a first enclosing plate 12 is arranged on the first platform 1, a second enclosing plate 22 is arranged on the second platform 2, and a groove 13 is formed between the first enclosing plate 12 and the second enclosing plate 22; the first enclosing plate 12 and the second enclosing plate 22 ensure that sand bodies accumulated on the first platform 1 and the second platform 2 cannot be scattered at the edges, and the grooves 13 ensure that a communicated sand accumulation space is always arranged above the first platform 1 and the second platform 2. Moreover, the first enclosing plate 12 is connected with the second enclosing plate 22 through a flexible plate, such as a flexible plastic plate or a flexible plastic cloth, so that when the first platform 1 and the second platform 2 move relatively, a gap at the joint of the first enclosing plate 12 and the second enclosing plate 22 cannot be spilled.

Specifically, on the basis of the fault simulation apparatus, the present embodiment further provides a fault simulation apparatus simulation method, which is shown in fig. 4 and includes the following steps:

step S100, adjusting the joint surface 33 in the inclined sliding table plate 3 to incline at a certain angle relative to the first platform 1; specifically, the first platen 31 and the second platen 32 may be replaced by corresponding angles between 0 and 90 degrees, including 90 degrees but not 0 degrees, such as a relative angle between the abutting surface 33 and the first platform 1 of 60 degrees.

Step S200, at least one layer of quartz sand is paved on the first platform 1 and the second platform 2, and a mark layer is paved on each layer of quartz sand.

Specifically, the mark layer refers to a sand layer which has a marking function and is different from the color of the quartz sand layer; multiple layers of quartz sand can be paved on the first platform 1 and the second platform 2, and the thickness of each layer of quartz sand is in the range of 1cm to 2cm, taking 1cm as an example. Wherein, the colour of quartz sand is mostly grey white, all lays the one deck and marks the layer on each layer of quartz sand, if lay three-layer quartz sand, red sign layer is laid to lower floor's quartz sand upside, lays blue sign layer on the middle level quartz sand, lays green sign layer on the quartz sand of the superiors, and so on.

Step S300, controlling the first platform 1 and the second platform 2 to perform relative linear displacement, relative torsional displacement or relative linear superimposed torsional displacement along the bonding surface 33.

Specifically, the driving mechanism 4 can be controlled to drive the first platform 1 and the second platform 2 to perform deformation such as pressure twisting, tension twisting, and hinge along the plane of the attachment surface 33, or perform superimposed deformation such as pressure twisting, tension twisting, and hinge.

Specifically, in step S300, the relative linear superposition of the torsional displacement includes the relative linear displacement and the relative torsional displacement which are alternately superposed, for example, the first platform 1 and the second platform 2 firstly perform a relative movement in the up-down direction along the plane direction of the adhering surface 33, and for example, the second platform 2 displaces upward along the adhering surface 33 relative to the first platform 1 to simulate a press-torsional deformation; and then the second platform 2 is controlled to deform relative to the hinge along the binding surface 33 relative to the first platform 1, so that the deformation of the pressure-torsion superposed hinge is simulated. And the second platform 2 moves downwards relative to the first platform 1 along the joint surface 33 to simulate tension and torsion deformation; and then the second platform 2 is controlled to deform relative to the hinge along the binding surface 33 relative to the first platform 1, so that the tension-torsion superposed hinge deformation is simulated. Such as the mentioned superposition mode, any mode of superposition deformation can be adopted in tension-torsion, compression-torsion and hinge deformation.

Specifically, when the relative linear superposition torsional displacement is carried out, after the relative linear displacement or the relative torsional displacement is carried out for one time, at least one layer of quartz sand is paved on the uppermost layer, a mark layer is paved on each layer of quartz sand, and then the next relative linear displacement or relative torsional displacement is carried out.

For example, after one time of pressure-torsion simulation deformation, at least one layer of quartz sand is paved on the upper side where the quartz sand is paved, a mark layer is paved above the quartz sand which is paved again, and next time of hinge deformation is carried out, so that the fault morphology change of pressure-torsion superposition hinge deformation can be simulated better through the mark layer.

Specifically, in step S300, in the relative linear displacement process, a planar image is acquired once every certain distance of displacement; during the relative torsion displacement, a plane image is acquired once every certain torsion angle.

Specifically, when the driving mechanism 4 drives the second platform 2 to linearly move along the plane where the adhering surface 33 is located relative to the first platform 1, such as when a pressing button or a tension button is simulated, the linear deformation displacement of the pressing button can be displaced for multiple times, that is, when the second platform 2 moves upward along the adhering surface 33 relative to the first platform 1, once planar shooting is performed along the opposite direction of the Z axis every certain displacement, and a planar image is obtained, so as to observe the gradual change process of the ground in the pressing button process. The hinge deformation is similar to the press-twist deformation, when the second platform 2 moves relative to the first platform 1 along the plane hinge where the binding surface 33 is located, once plane shooting is performed along the opposite direction of the Z axis every time the second platform rotates for a certain angle, and a plane image is obtained so as to observe the gradual change process of the ground in the hinge process.

Preferably, after step S300 is finished, at least one layer of quartz sand is laid on the uppermost layer, a certain amount of water is poured and left standing, and longitudinal sectioning is used for obtaining a section, wherein longitudinal sectioning refers to sectioning downwards with a surface parallel to a plane where the Z axis and the Y axis are located.

Specifically, based on the fault simulation method, the embodiment further provides a specific simulation method of a pressure-torsion superposition pivot, which specifically includes the following steps:

step S100, the initial states of the two platform planes of the first platform 1 and the second platform 2 are controlled to be adjusted to be the same horizontal plane and formed to be rectangular, the inclination between the joint surface 33 in the inclined sliding platform plate 3 and the first platform 1 is set to be 75 degrees, and the joint surface 33 inclines towards the opposite direction of the Y axis relative to the first platform 1.

Step S200, fixing the first platform 1 plane to surround the first enclosing plate 12 in three directions as a boundary, and fixing the second platform 2 plane to surround the second enclosing plate 22 in three directions as a boundary. The coaming is fixed by screws; fixing the joint of the first enclosing plate 12 and the second enclosing plate 22 by using a plastic film, then sequentially laying four layers of gray quartz sand with the thickness of 1cm on the platform surface from bottom to top, and using black, blue and pink as mark layers.

Step S310, carrying out first pivot fault simulation, controlling the rotation mechanism 44 and the turnover mechanism 45 to move so that the second platform 2 pivots towards the P direction along the axis vertical to the binding surface 33 for 5 degrees, and taking 2min when the second platform is used and the speed is 2.5 degrees/min; after rotating to the position, photographing is carried out along the Z-axis reverse direction to obtain a plane image.

After plane photographing, carrying out second pivot fault simulation, and controlling the rotating mechanism 44 and the turnover mechanism 45 to enable the second platform 2 to rotate 5 degrees in the P direction along the axis vertical to the binding surface 33, wherein the use time is 2min, and the speed is 2.5 degrees/min; after rotating to the position, photographing is carried out along the Z-axis reverse direction to obtain a plane image.

After plane photographing, carrying out third pivot fault simulation, and controlling the rotating mechanism 44 and the turnover mechanism 45 to enable the second platform 2 to rotate 5 degrees in the P direction along the axis vertical to the binding surface 33, wherein the use time is 2min, and the speed is 2.5 degrees/min; after rotating to the position, photographing is carried out along the Z-axis reverse direction to obtain a plane image.

After plane photographing, carrying out fourth pivot fault simulation, and controlling the rotating mechanism 44 and the turnover mechanism 45 to enable the second platform 2 to rotate 5 degrees in the P direction along the axis vertical to the binding surface 33, wherein the use time is 2min, and the speed is 2.5 degrees/min; after rotating to the position, photographing is carried out along the Z-axis reverse direction to obtain a plane image.

The pivot fault simulation carries out four times of equidirectional uniform motion and rotates 20 degrees.

Step S320, after the deformation is finished and the picture is taken in the step S310, a layer of white quartz sand with the thickness of 1.5cm is paved on the deformed sand layer to enable the plane to be even and horizontal, and green is used as a mark layer; and laying a layer of white quartz sand with the thickness of 0.5cm, and using red as a mark layer.

Carrying out right-hand movement pressing and twisting superposition pivot fault deformation once again, and controlling the first transverse moving mechanism 42 to enable the second platform 2 to move 1.2cm along the opposite direction of the X axis, wherein the time is 2min, and the speed is 0.6 cm/min; controlling the lifting mechanism 41 to enable the second platform 2 to move 0.4cm along the positive direction of the Z axis, wherein the time is 2min, and the speed is 0.2 cm/min; the first transverse moving mechanism 42 is linked with the lifting mechanism 41, and the first transverse moving mechanism 42 is controlled to enable the second platform 2 to move 0.107cm along the positive direction of the Y axis, the time is 2min, and the speed is 0.0535 cm/min; and after the displacement is in place, photographing is carried out along the Z-axis reverse direction to obtain a plane image.

After plane photographing, starting second right-going press-torsion superposition pivot fault deformation, and controlling the first transverse moving mechanism 42 to enable the second platform 2 to move 1.2cm along the X-axis reverse direction, wherein the time is 2min, and the speed is 0.6 cm/min; controlling the lifting mechanism 41 to enable the second platform 2 to move 0.4cm along the positive direction of the Z axis, wherein the time is 2min, and the speed is 0.2 cm/min; the first transverse moving mechanism 42 is linked with the lifting mechanism 41, and the first transverse moving mechanism 42 is controlled to enable the second platform 2 to move 0.107cm along the positive direction of the Y axis, the time is 2min, and the speed is 0.0535 cm/min; and after the displacement is in place, photographing is carried out along the Z-axis reverse direction to obtain a plane image.

After plane photographing, starting to perform right-hand movement, pressing and twisting for the third time and superposing with pivot fault deformation, and controlling the first transverse moving mechanism 42 to enable the second platform 2 to move 1.2cm along the opposite direction of the X axis, wherein the time is 2min, and the speed is 0.6 cm/min; controlling the lifting mechanism 41 to enable the second platform 2 to move 0.4cm along the positive direction of the Z axis, wherein the time is 2min, and the speed is 0.2 cm/min; the first transverse moving mechanism 42 is linked with the lifting mechanism 41, and the first transverse moving mechanism 42 is controlled to enable the second platform 2 to move 0.107cm along the positive direction of the Y axis, the time is 2min, and the speed is 0.0535 cm/min; and after the displacement is in place, photographing is carried out along the Z-axis reverse direction to obtain a plane image.

The right-hand press-twist moves in the same direction for three times, and the X-axis moves in the opposite direction for 3.6 cm; the positive direction of the Z axis is shifted by 1.2 cm; the positive direction of the Y axis is shifted by 0.321 cm.

After the whole simulation process is finished, laying 1cm of white quartz sand on the deformed sand layer, watering and standing, and longitudinally sectioning; and acquiring a longitudinal section, and performing interpretation analysis on the acquired plane image and the section image.

Specifically, fig. 6 is a plane evolution diagram of simulation results of deformation of a simulated piezoelectric-torsional superimposed hinge fault under a 75 ° pre-existing fault. As shown in fig. 6, after the deformation of the hinge fault displayed on the marker layer is finished (fig. 6b), marking lines with an interval of 6cm are drawn on the marker layer before the plane deformation starts, so that the result can be conveniently observed; it can be seen that the rising area of the second platform 2 is obviously raised, the falling area is obviously depressed, and the central area is slightly raised, so that the structural characteristics of the hinge fault can be embodied.

On the basis, after sand paving, right-hand pressing and twisting superposition pivot fault deformation is carried out by using a mark layer with another color (figure 6c), and mark lines with the interval of 6cm are drawn on the mark layer before plane deformation is started so as to facilitate observation results. When the deformation of the right-hand line pressure-torsion superposition pivot fault is finished (fig. 6d), it can be seen that the plane mark line is obviously broken, the middle part of the plane is obviously extruded and bulged, the right-hand line secondary fracture occurs, the boundary part develops horsetail-shaped fault layer combination, the equidirectional gliding fault (R fracture) phenomenon is obvious, the secondary equidirectional fault (P fracture) phenomenon is weakened, and a main displacement zone (PDZ) is gradually formed. This is basically consistent with the right row crumpling phenomenon.

Specifically, the sectional view (fig. 7) of the experimental result is explained, and the sectional view 7a of the slice is located in the descending region of the second platform 2 when the hinge is deformed, and the height of the second platform 2 after the compression-torsion deformation is lower than that of the first platform 1. The normal fault F1 and the reverse faults F2 and F3 can be seen in the section. It was concluded that F1 formed during hinge fault deformation, followed by compression-torsion to form F2, F3.

The section of the slice is shown in fig. 7b, which is located in the descending area of the second platform 2 when the hinge is deformed, and the height of the second platform 2 after the torsional deformation is equal to the height of the first platform 1. The reverse fault planes F1 and F2 are visible in the cross section. It is concluded that F1 is formed when the hinge fault is deformed, and that the post-buckling deformation formation is pushed along the pre-existing fault F1 and F2 is formed.

The section of the slice of fig. 7c is located at the center of the section of the hinge when the hinge is deformed, the height of the second platform 2 is not changed, and the height of the second platform 2 is higher than that of the first platform 1 after the hinge is deformed. The reverse fault F1 was seen in the cross section, from which it was concluded that F1 caused a phase of torsional deformation.

The section of the slice is shown in fig. 7d, which is located in the rising area of the second platform 2 when the hinge is deformed, and the height of the second platform 2 is higher than that of the first platform 1 after the hinge is deformed by pressing and twisting. The reverse fault planes F1 and F2 are visible in the cross section. It was concluded that F1 formed during hinge fault deformation, followed by a compression-torsion forming F2.

The invention relates to a structural physical simulation experimental device for simulating fault superposition deformation and an experimental result, wherein the structural physical simulation experimental device is designed and the operation method of the experimental device is explained according to the basic morphological characteristics of a fault; the deformation process characteristics of the right-travel pressure-torsion superposition pivot fault are simulated and reproduced by the physical simulation model, the deformation characteristics of the right-travel pressure-torsion superposition pivot fault are further explained by the variation phenomenon of each parameter in the simulation process, and the method aims to provide theoretical support for deep research of simulating superposition deformation of various faults, thereby providing theoretical basis for geological research.

Preferably, the control of the driving mechanism in the above simulation method may be controlled by an electronic device, and the electronic device provided by the present invention is described below, and the electronic device described below and the driving mechanism control process described above may be referred to correspondingly.

Fig. 8 illustrates a physical structure diagram of an electronic device, and as shown in fig. 8, the electronic device may include: a processor (processor)510, a communication Interface (Communications Interface)520, a memory (memory)530 and a communication bus 540, wherein the processor 510, the communication Interface 520 and the memory 530 communicate with each other via the communication bus 540. Processor 510 may invoke logic instructions in memory 530 to execute the drive mechanism control process.

Furthermore, the logic instructions in the memory 530 may be implemented in the form of software functional units and stored in a computer readable storage medium when sold or used as a stand-alone product. Based on such understanding, the technical solution of the present invention may be embodied in the form of a software product, which is stored in a storage medium and includes instructions for causing a computer device (which may be a personal computer, a server, or a network device) to execute all or part of the steps of the method according to the embodiments of the present invention. And the aforementioned storage medium includes: a U-disk, a removable hard disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a magnetic disk or an optical disk, and other various media capable of storing program codes.

In another aspect, the present invention also provides a computer program product comprising a computer program stored on a non-transitory computer readable storage medium, the computer program comprising program instructions which, when executed by a computer, enable the computer to perform the drive mechanism control process provided by the above-mentioned methods.

In yet another aspect, the present invention also provides a non-transitory computer-readable storage medium having stored thereon a computer program that, when executed by a processor, is implemented to perform the drive mechanism control process provided above.

The above-described embodiments of the apparatus are merely illustrative, and the units described as separate parts may or may not be physically separate, and parts displayed as units may or may not be physical units, may be located in one place, or may be distributed on a plurality of network units. Some or all of the modules may be selected according to actual needs to achieve the purpose of the solution of the present embodiment. One of ordinary skill in the art can understand and implement it without inventive effort.

Through the above description of the embodiments, those skilled in the art will clearly understand that each embodiment can be implemented by software plus a necessary general hardware platform, and certainly can also be implemented by hardware. With this understanding in mind, the above-described technical solutions may be embodied in the form of a software product, which can be stored in a computer-readable storage medium such as ROM/RAM, magnetic disk, optical disk, etc., and includes instructions for causing a computer device (which may be a personal computer, a server, or a network device, etc.) to execute the methods described in the embodiments or some parts of the embodiments.

Finally, it should be noted that: the above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims (11)

1. A fault simulation device is characterized by comprising a first platform, a second platform, an inclined sliding platen and a driving mechanism, wherein the inclined sliding platen comprises a first platen and a second platen, the first platen is connected with the first platform, and the second platen is connected with the second platform;

the first bedplate is attached to the second bedplate, and an attaching surface between the first bedplate and the second bedplate is inclined relative to a first table top of the first platform;

the driving mechanism is used for driving the first platform and the second platform to perform relative linear displacement, relative torsional displacement or relative linear superposition torsional displacement along the binding face.

2. The fault simulation device of claim 1, further comprising a controller electrically connected to the driving mechanism, and configured to control a displacement speed, a displacement distance, and a displacement direction at which the driving mechanism drives the first platform and the second platform to move linearly relative to each other along the abutting surface, or to control a displacement speed, a displacement distance, a displacement angle, and a displacement direction at which the driving mechanism drives the first platform and the second platform to move torsionally relative to each other or to linearly superimpose the torsional displacement along the abutting surface.

3. The fault simulator of claim 1 or 2, wherein the driving mechanism comprises a lifting mechanism and a first transverse moving mechanism, the lifting mechanism is connected with the second platform and used for driving the second platform to move up and down, and the first transverse moving mechanism is connected with the second platform and used for driving the second platform to move in a horizontal direction.

4. The fault simulator of claim 1 or 2, wherein the driving mechanism comprises a second traverse mechanism connected to the first platform for driving the first platform to move in a horizontal direction.

5. The fault simulator of claim 1 or 2, wherein the driving mechanism comprises a rotating mechanism and a tilting mechanism, and the second platform has a second table top;

the rotating mechanism is connected with the second platform and used for driving the second platform to rotate, and the rotating axis of the second platform is vertical to the second table top;

the turnover mechanism is connected with the second platform and used for driving the second platform to turn over, a turnover axis of the second platform is intersected with the rotation axis and is mutually vertical, and the plane where the turnover axis is located is vertical to the binding surface.

6. The fault simulation device of claim 1, wherein the first platen is removably coupled to the first platform and the second platen is removably coupled to the second platform.

7. The fault simulation device of claim 1, wherein a first enclosing plate is arranged on the first platform, a second enclosing plate is arranged on the second platform, and the first enclosing plate and the second enclosing plate enclose to form a groove;

the first enclosing plate is connected with the second enclosing plate through a flexible plate.

8. A simulation method based on the fault simulation apparatus according to any one of claims 1 to 7, characterized by comprising the steps of:

s100, controlling a binding surface in the inclined sliding table plate to incline at a certain angle relative to the first platform;

s200, laying at least one layer of quartz sand on a first platform and a second platform, wherein each layer of quartz sand is laid with a mark layer;

and S300, controlling the first platform and the second platform to perform relative linear displacement, relative torsional displacement or relative linear superposition torsional displacement along the binding surface.

9. The simulation method according to claim 8, wherein in the step S300, the relative linear superposition of the torsional displacement includes a relative linear displacement and a relative torsional displacement interval superposition;

when the relative linear superposition torsional displacement is carried out, after one relative linear displacement or relative torsional displacement is carried out, at least one layer of quartz sand is paved on the uppermost layer, a mark layer is paved on each layer of quartz sand, and then the next relative linear displacement or relative torsional displacement is carried out.

10. The simulation method according to claim 8 or 9, wherein in the step S300, a planar image is obtained once every certain distance of displacement in the relative linear displacement process; during the relative torsion displacement, a plane image is acquired once every certain torsion angle.

11. The simulation method according to claim 8 or 9, wherein at least one layer of quartz sand is laid on the uppermost layer after the step S300 is finished, a certain amount of water is poured and left standing, and a longitudinal section is cut for obtaining a section.

Images